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Abstract

A soft morphing ray propulsor capable of generating an undulating motion in its pectoral fins was designed and fabricated. The propulsor used shape memory alloy for actuation, and the body was made with soft polymers. To determine the effects of undulation in the fins, two models that differed in terms of the presence of undulation were fabricated using different polymer materials. The experimental models were tested with a dynamometer to measure and compare thrust tendencies. Thrust measurements were conducted with various fin beat frequencies. Using the experimental data, the concept of an optimized standalone version of the ray robot was suggested and its prototype was fabricated. The fabricated robot was able to swim as fast as 0.26 body length per second and 38% more efficient than other smart material-based ray-like underwater robots.

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References

Webb

. Form and function in fish swimming. Sci Am, 1984; 251:72–82.

Griffiths

. Technology and Applications of Autonomous Underwater Vehicles. Florida: CRC Press, 2003.

Sfakiotakis

, Lane

, Davies

JBC

. Review of fish swimming modes for aquatic locomotion. IEEE J Oceanic Eng, 1999; 24:237–252.

Wen

, Weaver

, Lauder

. Biomimetic shark skin: design, fabrication and hydrodynamic function. J Exp Biol, 2014; 217:1656–1666.

Kim

, Kim

, Jung

, Park

. A biomimetic undulatory tadpole robot using ionic polymer–metal composite actuators. Smart Mater Struct, 2005; 14:1579.

McCleave

. Swimming performance of european eel (Anguilla Anguilla (L.)) elvers. J Fish Biol, 1980; 16:445–452.

Schaefer

, Summers

. Batoid wing skeletal structure—novel morphologies, mechanical implication, and phylogenetic patterns. J Morphol, 2005; 264:298–313.

Breder

. The locomotion of fishes. Zoologica, 1926; 4:159–256.

Rosenberger

. Pectoral fin locomotion in batoid fishes: undulation versus oscillation. J Exp Biol, 2001; 204:379–394.

10.

, Cai

, Wang

, Bi

, Gong

. A biomimetic cownose ray robot fish with oscillating and chordwise twisting flexible pectoral fins. Ind Rob, 2015; 42:214–221.

11.

Wang

, Wang

, Li

, Hang

. A micro biomimetic manta ray robot fish actuated by SMA. IEEE International Conference on Robotics and Biomimetics (ROBIO); Dec 19–23, 2009, pp. 1809–1813.

12.

Takagi

, Yamamura

, Luo

, Onishi

, Hirano

, Asaka

, et al. Development of a rajiform swimming robot using ionic polymer artificial muscles. IEEE/RSJ International Conference on Intelligent Robots and Systems; Oct 9–15, 2006, pp. 1861–1866.

13.

Chen

, Um

, Bart-Smith

. Bio-inspired robotic manta ray powered by ionic polymer-metal composite artificial muscles. Int J Smart Nano Mater, 2012; 3:296–308.

14.

Cloitre

, et al. Propulsive performance of an underwater soft biomimetic batoid robot. The Twenty-Fourth International Ocean and Polar Engineering Conference. International Society of Offshore and Polar Engineers, June 15–20, 2014, Busan, Korea.

15.

Quinn

, Lauder

, Smits

. Scaling the propulsive performance of heaving flexible panels. J Fluid Mech, 2014; 738:250–267.

16.

Song

, Lee

, Rodrigue

, Choi

, Kang

, Ahn

. 35 Hz shape memory alloy actuator with bending-twisting mode. Sci Rep, 2016; 6:Article No. 21118.

17.

Lee

, Kim

, Park

, Kim

, Song

, Kim

, et al. Shape Memory Alloy (SMA)-based head and neck immobilizer for radiotherapy. J Comput Des Eng, 2015; 2:176–182.

18.

Rodrigue

, Wang

, Bhandari

, Han

, Ahn

. Cross-shaped twisting structure using sma-based smart soft composite. Int J Precis Eng Manuf Green Technol, 2014; 1:153–156.

19.

Ahn

, Lee

, Kim

, Wu

, Kim

, Song

. Smart Soft Composite: an integrated 3d soft morphing structure using bend-twist coupling of anisotropic materials. Int J Precis Eng Manuf, 2012; 13:631–634.

20.

Wang

, Rodrigue

, Lee

, Han

, Ahn

. Smartphone robot made of smart soft composite (SSC). Compos Res, 2015; 28:52–57.

21.

Blevins

, Lauder

. Swimming near the substrate: a simple robotic model of stingray locomotion. Bioinspiration Biomimetics, 2013; 8:016005.

22.

Clark

, Smits

. Thrust production and wake structure of a batoid-inspired oscillating fin. J Fluid Mech, 2006; 562:415–429.

23.

Read

, Hover

, Triantafyllou

. Forces on oscillating foils for propulsion and maneuvering. J Fluids Struct, 2003; 17:163–183.

24.

Park

, Jeong

, Lee

, Kwon

, Kim

, Cho

. Kinematic condition for maximizing the thrust of a robotic fish using a compliant caudal fin. IEEE Trans Rob, 2012; 28:1216–1227.

25.

Schultz

, Webb

. Power requirements of swimming: do new methods resolve old questions?. Integr Comp Biol, 2002; 42:1018–1025.

26.

Di Santo

, Kenaley

. Skating by: low energetic costs of swimming in a batoid fish. J Exp Biol, 2016; 219:1804–1807.

27.

Chu

, et al. Review of biomimetic underwater robot using smart actuators. Int J Precis Eng Manuf, 2012; 13:1281–1292.

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Design and Fabrication of Soft Morphing Ray Propulsor: Undulator and Oscillator

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